1. Principles of Enzyme Catalysis

2. Thermodynamics is concerned with only the initial and final states of a process, being independent of the path(s) between the two states. Kinetics is concerned with the rate at which the process occurs and thus is concerned with the path(s) between the two states. The parable of the sugar packet

3. Wolfenden, R. (2003) Thermodynamic and extrathermodynamic requirements of enzyme catalysis. Biophys. Chem. 105, 559-572. Time Scale for Selected Biochemically Important Reactions Carbonic anhydrase k cat = 20 x 10 6 s -1

5. Collision Theory k = (  k B T/h) C 1-n e -  G‡/RT The rate constant for the reaction is inversely proportional to the height of the barrier (  G ‡ ) but proportional to temperature is proportional to the concentration of reactants Kinetic energy Number of molecules Boltzmann distribution G‡G‡ is proportional to the probability of a productive collision

6. Encounter Complex As two reactants diffuse together they become caged by the surrounding water molecules. In this encounter complex there is a greater probability that the reactants will collide rather than diffuse apart.

7.  G =  H -T  S  G ‡ =  H ‡ -T  S ‡

8. Potential Mechanisms for Enzyme Catalytic Efficiency By binding substrates in the active site, enzymes can increase the effective local concentrations of reactants (Proximity effects) Substrate binding can correctly orient reacting groups in the active site (Orbital steering) Enzymes can promote desolvation upon substrate binding Enzymes can enhance the inherent reactivity of functional groups by altering the microenvironment within the active site

9. Entropy-Enthalpy Compensation The unfavorable entropy of activation (  S ‡ ) of bringing the reactants together into the encounter complex is compensated by the favorable enthalpy of binding (  H) of the reactants in the active site. By binding substrates in the active site, enzymes can produce effective concentrations orders of magnitude greater than can be achieved in the absence of the catalyst.

10. Proximity Effects

11. Induced Fit (Transition State Binding) Wolfenden, R. (2003) Biophys. Chem. 105, 559-572

12. Induced Fit (Transition State Binding) Methotrexate Aminopterin

13. Microenvironment Effects Mechanism of Acetoacetate Decarboxylase

14. Ho et al. (2009) Nature 459, 393-397

15. Ramped N-terminus to C-terminus Lys 115 Substrate Schiff base Arg 29 Ho et al. (2009) Nature 459, 393-397

16. General Acid-Base Catalysis Human Pancreatic Ribonuclease His 219 His 112 N C

17. General Acid-Base Catalysis Mechanism of Ribonuclease

18. C E35 D52 C Rings A-D Induced Fit in the Mechanism of Lysozyme

19. Vocadlo et al. (2001) Nature 412, 835-838

20. Covalent Catalysis in the Serine Proteases Ser 195 His 57 Asp 102